Sodium-ion batteries are an alternative to lithium-ion batteries for large-scale applications. However, low capacity and poor rate capability of existing anodes are the main bottlenecks to future developments. Here we report a uniform coating of antimony sulphide (stibnite) on graphene, fabricated by a solution-based synthesis technique, as the anode material for sodium-ion batteries. It gives a high capacity of 730 mAh g À 1 at 50 mA g À 1 , an excellent rate capability up to 6C and a good cycle performance. The promising performance is attributed to fast sodium ion diffusion from the small nanoparticles, and good electrical transport from the intimate contact between the active material and graphene, which also provides a template for anchoring the nanoparticles. We also demonstrate a battery with the stibnite-graphene composite that is free from sodium metal, having energy density up to 80 Wh kg À 1 . The energy density could exceed that of some lithium-ion batteries with further optimization.
An anode material incorporating a sulfide is reported. SnS nanoparticles anchored onto reduced graphene oxide are produced via a chemical route and demonstrate an impressive capacity of 350 mA h g, exceeding the capacity of graphite. These results open the door for a new class of high capacity anode materials (based on sulfide chemistry) for potassium-ion batteries.
The Cambridge Structural
Database has been used to investigate
the detailed environment of H2O2 molecules and
hydrogen-bond patterns within “true” peroxosolvates
in which the H2O2 molecules do not interact
directly with the metal atoms. A study of 65 crystal structures and
over 260 hydrogen bonds reveals that H2O2 always
forms two H-bonds as proton donors and up to four H-bonds as a proton
acceptor, but the latter can be absent altogether. The necessary features
of peroxosolvate coformers are clarified. (1) Coformers should not
participate in redox reactions with H2O2 and
should not catalyze its decomposition. (2) Coformers should be Brønsted
bases or exhibit amphoteric properties. The efficiency of the proposed
criteria for peroxosolvate formation is illustrated by the synthesis
and characterization of several new crystals. Conditions preventing
the H2O2/H2O isomorphous substitution
are essential for peroxosolvate stability: (1) Every H2O2 in the peroxosolvate has to participate in five or
six hydrogen bonds. (2) The distance between the two proton acceptors
forming H-bonds with the H2O2 molecule should
be longer than the distance defined by the nature of the acceptor
atoms.
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